semiconductor nanostructure tagged posts

By evaporating indium gallium arsenide onto a gallium arsenide substrate TUM physicists created nanometer-scale hills, so-called quantum dots. An electron trapped in one of these quantum dots can be used to store information. Hitherto unknown memory loss mechanisms could be switched off by applying a magnetic field. Credit: Fabian Flassig / TUM

Magnetic field helps qubit electrons store information longer. Physicists have tracked down semiconductor nanostructure mechanisms that can result in the loss of stored information – and halted the amnesia using an external magnetic field. The new nanostructures comprise common semiconductor materials compatible with standard manufacturing processes.

In principle, there are various possibilities of implementing qubits: photons are an option equally ...

>>could improve Med Imaging/ Cancer Rx’s + Increase Solar Cell efficency by 25 – 30%. Goal is to turn low-energy colors of light, such as red, into higher-energy colors, like blue/green. A traditional solar cell can only absorb light with energy above a certain threshold. Infrared light passes right through, its energy untapped. But if low-energy could be transformed into higher-energy light, a solar cell could absorb more.

UD’s College of Engineering’s A/Prof Matthew Doty said; “You can’t simply turn a red photon into a blue one, but you can combine the energy from two or more red photons to make one blue photon.” …”Photon upconversion” isn’t new but UD team’s approach is. They want to design a new kind of semiconductor nanostructure that will act like a ratchet...